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An overview of uranium exploration strategy in IndiaByAnjan ChakiDirectorAtomic Minerals Directorate for Exploration and ResearchDepartment of Atomic EnergyGovernment of India
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Outline
• Uranium provinces of India• India’s uranium exploration history• Exploration strategy for Srisailam-Palnad-Kurnool sub-basins• Exploration strategy for Southern Cuddapah basin• Exploration strategy for North Delhi Fold Belt• Exploration strategy for Cretaceous Mahadek basin• Exploration strategy for Proterozoic Bhima basin• Exploration strategy for Proterozoic Kaladgi basin• Concluding remarks
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Kaladgi basin, Karnataka
Bhima basin, Karnataka
Cuddapah basin,Andhra Pradesh
Srisailam, Palnad and Kurnool sub-basins,Cuddapah basin
Mahadek basin, Meghalaya
Singhbhum Shear Zone, Jharkhand
North Delhi Fold Belt, Rajasthan and Haryana
Major Uranium Provinces of India
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History of uranium exploration in IndiaExploration started in early 1950’s11 deposits ( > 500 t U3O8 of grade: 0.02-0.06% U3O8) proved between 1951-1975New discoveries from widely different geological settings in Rajasthan and HimalayasNew Uranium provinces viz. SSZ, Southern Cuddapah and Mahadeks establishedSix Cretaceous sandstone type U-deposits in Meghalaya – Gomaghat(1974), Domiasiat (1983-92),Wakhyn (1995-2007) etc. establishedProterozoic Cuddapah Basin emerge as a major uranium province. Tummalapalle(1984 to present) in Dolostone hosted strata-bound, Lambapur-Peddagattu-Chitrial (1992-Present) in unconformity-relatedProterozoic Bhima Basin – Gogi (1999-2002) – Vein typeProterozoic vein type U deposit in Rajasthan – Rohil – Ghateshwar(2000-Present)Proterozoic Kaladgi basin – Emerging
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Srisailam-Palnad-Kurnool sub-basins
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Srisailam-Palnad sub-basins, Cuddapah basin
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Northern and north-western part of Cuddapah basin is the host for unconformity related uranium mineralisationThe formations are of Middle to Upper Proterozoic ageUnmetamorphosed sediments of orthoquartzite, limestone and shaleThree low grade – low tonnage deposits have been established in Lambapur - Peddagattu, Koppunuru and Chitrial in the northwestern periphery of Cuddapah basinNearly 60 sq.km area unexplored in Chitrial and Peddagattu deposits3000 sq.km inside the basin under sanctuary holds high potential is yet to be exploredPrognostic reserves of Chitrial deposit is about 30,000 tonnes of U3O8
Uranium mineralisation in northwestern parts of Cuddapah basin
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Lower Proterozoic granite unconformablyoverlain by Middle Proterozoic Srisaialamformation Uranium mineralisation follows the unconformity contact between the SrisailamFormation and graniteMajor part of the mineralisation is confined to basement granitesPitchblende, Uraninite, Coffinite and Uranophane are uranium minerals
Uranium mineralisation in northwestern parts of Cuddapah basin
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Exploration strategy for unconformity related deposits in Cuddapah basin
Radiometric and Geological mappingRadiometric logging of groundwater tubewellsAirborne and ground based geophysical surveys (TDEM, Magnetic and Radiometrics)Geochemical, petro-minerological and isotopic characterisationof ore body and host rocksHyper-spectral Remote Sensing for alteration mappingDrill cores- mineral alteration studiesGroundwater hydrology Genetic modeling of uranium mineralisation
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Southern Cuddapah basin
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Southern Cuddapah uranium province
Granites, gneissic rocks, Dharwar schists------------------- non-conformity ---------------------
Papagni group - Vempalle FormationLimestone, dolostoneshale, chert
Gulcheru quartzite
-------------------- disconformity ----------------------
Chitravati group
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Nature of host rock Impure, siliceous, phosphatic, dolomitic stromatolitic limestone
Uranium Minerals Pitchblende , Coffinite, U-Ti complex, Collophane
Associated minerals Pyrite, Chalcopyrite, Molybdenite bornite, digenite, covellite
Gangue Minerals Dolomite, Quartz, Microcline
Average Grade 0.040 to 0.046% eU3O8
Trace Elements Molybdenum - 230 ppm Nickel - 30 ppmCopper - 90 ppmCobalt - 25 ppmBarium - 215 ppmP2O5 - 2.46%
Controls of mineralisation Phosphate, silica and organic matter in the impure dolomitic limestone are the main controlling factors for uranium mineralisation
Characteristics of uranium mineralisation in Vempalle dolostone
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Thin alternating light and medium to dark gray color bands. Light gray bands are fine grained and rich in carbonates (micritic andsparritic) mostly dolomites.
Medium to dark grey bands are ultrafine and rich in phosphates mostlycollophane
These bands contain floating grains of detrital quartz, felspars andopaques (pyrites).
Uranium mineral - `pitchblende’ which occurs as ultrafine granular aggregate, in intimate association with both biogenic and diageneticpyrite
Other primary uranium minerals in minor amounts are coffinite and U-Ti complex.
Coffinite is later to pitchblende, as it replaces the boundaries and fracture plane. U-Ti complex is present as stringers and inclusion in clasticquartz.
Petrography of Vempalle Dolostone
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Shallow inter tidal flat / mud flat sediments -- Mud cracks, ripple marks, intraforamtional conglomerate layers
Organic activity /deposition of algal debris -- Secondary structures like secretion nodules, oolites and stromatolites
Source of uranium -- Fertile basement granite in the SW3 stages of uranium concentration
Syngenetic stage : Adsorbed U in phosphate - Algal debris created reducing environment leading to the formation of pyrite and precipitation of uranium
Diagenetic stage : Dolomitisation/ formation ofmicrostylolites and uranium mineralisation
Epigenetic stage : Pitchblende, coffinite in grain boundaries, micro fractures, bedding planes
Genesis of uranium mineralisation
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Tabular, stratabound, non-transgressive ore zones, homogenousMineralisation extends for 160 km along the strike Limited variation in grade and thickness along strike as well as in dip directionsTwo ore lodes – separated by 3m (average) lean zoneBasic dyke which lies in the centre of the deposit has not disturbed the continuity of the mineralization
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Extensive Drilling -- 160 km long belt of near-isotropic(?) uranium mineralisation along the strikeSedimentary facies mapping of massive / cherty limestones of Vempalle Formation to identify pockets of higher grade mineralisationGeochemical characterisation and genetic modeling for U, Mo and other elements in the orebody and provenance rocksConstruction of mine and mill in progress
Exploration strategy
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North Delhi Fold Belt
V VVV V
V VV
V VVV
VV VVV
V V V VVV
V V V VV
VVV
VV
V VVV
V
Vrrrr
r rr rrrr
J J J JJ J J J
J JJ J
J JJ
J J J JJJJJ JJ J J
JJJ J
J
J JJJ
J
J JJ J
J J J
JJ J
J
J
J J
aaaa
J
a
VaJ
V
Barmer
JaisalmerBadhaura
Jodhpur
Pali
Jalor
Nagaur
Jhunjhunu
Sikar
Ladi-ka-basKalatopri
JAIPUR
Alwar
BharatpurDiara
Rohil - Ghateshwar
Kushlawali DhaniPanchlangi
KerpuraKaroth Ki Dhanian
Mewaragujarwas
Siswali
Dhanota
SiorKanthiAntri
Goga TempleBadhaura
Swai Madhopur
Kunchalwara
Devpura
BundiBhilwara
KherpuraPutholi
ChitorgarhJhalawar
UdaisagarUmra
PrasadPalanpur
Dungapur
Banswara
Kota
KalamagraUdaipur
Haldughati
Kharbar
Durgapura
0 50 100 km
24°00'
26°00'
28°00'
26°00'
28°00'
Hy derabad
GEOLOGICAL MAP OF PART OF RAJASTHAN SHOWING URANIUM OCCURRENCES
r r
24°00'
70° 00' 72° 00' 74° 00'76° 00'
78° 00'
72° 00'
74° 00'76° 00'
AlluviumSandstone & Conglomerate/LateriteDeccan TrapAbur BedsJurassic FormationsBap BedsVindhyan SupergroupMalani RhyoliteErinpura GraniteDelhi SupergroupRaialo SeriesAravalli Supergroup/Basic & Ultrabasic RocksGranite/Nepheline SyeniteBanded Gneissic Complex (BGC)Uranium Occurrence
Umra
Rohil-Ghateshwar
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Uranium mineralisation intermittently along 320 km long east west trending Kaliguman lineamentNorth Delhi fold belt lies in the northern part of the lineamentComprise Khetri, Alwar and Lalsot-Bayana sub-basinsMiddle Proterozoic Metasedimentary rocks with acidic intrusivesExtensive albitisationEstablished a low grade – low tonnage uranium deposit in Rohil villageScope for similar mineralisation along the 320 km long lineament in other sectors.
Uranium potential of North Delhi Fold Belt
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Disposition of orebody and surface projection - Rohil
RHL-15
RHL-26
RHL-21
RHL-20
RHL-13A
RHL-39ARHL-17
RHL-24&27
Scale
GEOLOGICAL MAP SHOWING BOREHOLES LOCATION OF ROHIL AREA ( CENTRAL BLOCK ) DISTT. SIKAR , RAJASTHAN TOPOSHEET NO. 45M/6
100m 50m 0m 100m
RHL-36
GTR-76
GTR-77
GTR-74GTR-79
GTR-73
GTR-78
RHL-32
GTR-71 RHL-31
400m200m 300m 500m
RHL-35
GTR-67
GTR-21
GTR-12
GTR-18
GTR-25
GTR-65
GTR-26ARHL-33
RHL-30
RHL-28
GTR-40
GTR-22GTR-55&62
GTR-14
GTR-19
GTR-11
GTR-37&47
GTR-39 RHL-16
GTR-28
GTR-68
GTR-32
GTR-7
GTR-10
GTR-30
GTR-5
GTR-59
GTR-38 RHL-14
GTR-34
GTR-63
GTR-33
GTR-8
GTR-45&51
GTR-46(Ab)
RHL-25
RHL-41
RHL-37
RHL-39
RHL-18
GTR-86
RHL-42RHL-38
RHL-19RHL-44
RHL-34
RHL-43RHL-22
RHL-40
RHL-23RHL-29
INDEXSOIL COVER
QUARTZITE
SHEAR ZONE/FAULT
SURVEY STATION
CONDUCTOR AXIS
N
CENTRAL BLOCK
100 N
200 N
300 N
400 N
500 N
600 N
700 N
800 N
900 N
1000 N
100 S
0
100 S
0
100 N
200 N
300 N
400 N
500 N
600 N
700 N
900 N
800 N
1000 N
1100 N
300
W
400
W
200W 200 E
100 E
300 E
400 E
500 E
600E0
0
100
W
700E
800E
NORT
HING
(Y)
EASTING (X)
RHL 47A
R O H I L
N- 1
00-N
0-S1
N- 2
N- 3
N- 4
N- 5
N-6
N- 7
N- 8
N- 9
N- 10
N- 11
GTR-81
GTR-48
GTR-58
GTR-24
RHL-46
GTR-43ARHL-45
A-1
A-1
A
A
B
BB-1
B-1B-2
B-2
E-1
E-1
Samadhi
School
Projected U-Lodes
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Mineralisation along shear zones and fracturesConfined to albitised meta-pelitic rocks and neighborhoodMineralisation is associated with massive sulphide mineralsSulphide minerals are manifested as good conductors in the ground and airborne electromagnetic data/imagesAreas of hydrothermal activity represented by a low magnetic zone as a result of alteration of minerals of high magnetic susceptibilityAxial planes are the zones of intense shearing
Characteristics of uranium mineralisation - Rohil
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Area is mostly covered by quaternary alluviumGeological and radiometric study of scanty outcropsHydro-geochemical surveysRadiometric logging of pre-existing groundwater tube wellsAreas along the Kaliguman lineament with
area of albitisationlinear low magnetic zonesassociation of high conductorsassociation of shear/fracture zone and axial planes of folds
are the signatures for possible uranium mineralisation in NDFBMathematical modeling of geological and geophysical datasetsExploration programme stresses on extensive airborne geophysical surveys and a matching drilling campaign
Exploration strategy for NDFB
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Mahadek basin
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Upper Cretaceous Lower Mahadek sediments are the host for Sandstone type uranium mineralisation in Meghalaya, IndiaMeghalaya plateau in northeast India is a horst block uplifted during Eocene along with Himalayan orogenySouthern part of Meghalaya plateau is exposed with 1800 sq.km of Cretaceous and Tertiary sedimentsTwo medium grade low tonnage deposits and four satellite deposits have been established in this provinceLower Mahadek sediments (thickness-30-40m) are of fluvial nature and characterised by Channel filled and flood plain sedimentsLower Mahadek sediments are exposed over 500 sq.km area, while in the remaining 1300 sq.km, they are overlained by younger Tertiary sedimentsThe channel filled sediments of the lower Mahadeks are the target horizon for sandstone type of Uranium mineralisation
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Correlation sections of Domiasiat uranium deposit
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Deposited as tabular/peneconcordant body alongpalaeo channels of basement topographic lows in a proximal braided channel systemAverage vertical impact is 30mPitchblende, uraninite, coffinite, U+Si+C complex & secondary uranyl complexes are the uranium minerals73 - 92% laechability by pug Cure, hot agitation & conventional leachingAssociated elements are V, As, Co, Se, Mo, Organic matter : 0.5 to 1%
Domiasiat-Wahkyn uranium deposits
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Uranium exploration strategyMahadek sediments -- 500 sq.km exposed : Radiometric surveys done; rest 1300 sq.km covered by upto 300m thick pile of Tertiary sedimentsMost of the area under thick forest cover and wild life sanctuaryMicro-geomorphological studies using aerial photos and high resolution satellite images for the delineation of Channel sediments and Flood plain sediments among the exposed parts of Lower MahadeksGround magnetic and resistivity surveys for the delineation of palaeo-channels and basement lowsOther geophysical inputs
* TDEM for delineation of palaeo channels where the targetis covered by a thick pile of Tertiary sediments
* Gamma-ray spectrometer survey* Magnetics and Resistivity surveys for basement topography* Drilling with geophysical logging
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Bhima basin
F F
FF
FF
F
F
F
F
76 150 '
170'
GEOLOGICAL MAP OF BHIMA BASIN5 0 5 10 15Km
LATERITEDECCAN TRAPCHERT BEDS (INTER - TRAPPEANS)PURPLE SHALE(HARWAL Fm.)LIMESTONE( KATAMDEVARHALLI Fm.)SAND STONE/ SHALE(HALKAL Fm.)LIMESTONE(SHAHABAD Fm)SHALE
DYKEYOUNGER GRANITEYOUNGER SCHIST BELTPENINSULAR GNEISSOLDER SCHIST BELT (SARGUR)
ARENITE
FAULTF F
INDEX
SURFACE RADIOACTIVITY
Kagna river
FF
Fracture zone
(RABANPALLI Fm)
F F
F FF
F
F F
NEW
S
76 300 ' 76 450 ' 77 0 77 150 ' 77 300 '160
'15
160'30
160'45
170'15
GOGI
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Characteristics of uranium mineralisation in Gogi area
Small – medium grade depositUranium mineralisation associated with tectonised limestone and sheared basement granitesMineralisation in the environs of thrust plane and unconformity Coffinite and pitchblende are major uranium mineralsMineralisation is intimately associated with carbonaceous matterAlteration in basement are chloritisation and sericitisation
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1. Wadi fault zone 2. Karankot – Kallur 3. Wajhal – Tintini4. Sedam – Ekmai 5. Santi – Achola: 6. Shahabad – Bankur
Hydro uranium anomaly zones
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Exploration strategyRadiometric and Geological mappingGeochemical, petro-minerologicalcharacterisation of ore body and host rocksAirborne and ground based geophysical surveys (TDEM, Magnetic and Radiometrics)Radiometric logging of groundwater tubewellsGenetic modeling of uranium mineralisation
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Kaladgi basin
After Geological Society of India, 1999
Total aerial extent ~ 8500 sq km
Hungund Schist Belt2.7 Ga, Au-bearing
Closepet Granite2.5Ga, U & Th rich Peninsular Gneiss
3.3-3.0 & 2.7-2.6 GasChitradurga Schist Belt2.6Ga, U anomalies
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Reduced nature of the radioactive corePresence of rich sulphides in the mineralized portions in dispersed form as well as fracture fillingsReplacement of sulphide (pyrite) by the uranium phase.Presence of secondary uranium mineralAbsence of oxidized basement schist below the Absence of oxidized basement schist below the unconformity unconformity Higher concentration of uranium mineralization and the associated sulphides in structurally weak zones and in paleo-lows.
Uranium mineralisation in Kaladgi sediments
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Nature of host rock Quartz arenite
Uranium Minerals Pitchblende, Uraninite, Brannerite and secondary uranium
Associated minerals Pyrite, hematite and limonite
Alteration Secondary silica overgrowth, replacement of pitchblende along borders and fractures of pyrites
Controls of mineralisation Hydrothermal epigenetic along fractures and weak planes
Uranium mineralisation in Kaladgi sediments
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The anomaly amplitudes decreases towards SW indicating the increase in the sediment thickness The high gradient in NE may be due to NW-SE trending structural dislocationLocalized N-S trending gravity low in the vicinity of boreholes DNR-13 and DNR-17 is proved to be mineralized. Hence such lows may form favourable locales..
Gravity Survey, Deshnur area
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Magnetic Image suggest the N – S feature associated with mineralisation
Magnetic Surveys in Deshnur area
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Indian uranium deposits – a comparison
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India’s Uranium Resources through the years
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Concluding remarks
• India has vast low grade uranium resources in Cuddapah basin
• Very high potential to host high grade unconformity related mineralisation in the Proterozoic basins
• India has 14 Proterozoic basins, of which three known to host unconformity related uranium deposits hosted and vein type mineralisation – Potential for huge uranium resources
• Areas in Rajasthan along Kaliguman lineament is open for exploration
• Uranium mineralisation has been established in all the other Proterozoic basins
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Future strategy
� Uranium exploration in India is now geared up to face the challenges of the rapidly growing domestic nuclear power sector and has carefully laid down plans for the next five to ten years. � Airborne Time Domain Electromagnetic surveys have been introduced in a big way in the uranium exploration programme of the country. More than 4,00,000 line km of airborne geophysical surveys, including TDEM, Gamma-ray spectrometric and magnetic surveys are proposed to be carried out over potential Proterozoic Basins of India. � An ambitious drilling programme to drill about 7,00,000m in potential target areas of the country has already been formulated in order to augment the uranium resources.
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Thanks
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